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World enough and form: Why cosmology needs hylomorphism Author: John G. Brungardt Affiliation: Pontificia Universidad Católica de Chile, Instituto de Filosofía Address: Pontificia Universidad Católica de Chile Instituto de Filosofía Av. Vicuña Mackenna 4860 Santiago 7820436 Región Metropolitana Chile Contact: jobrungardt@uc.cl ORCID: 0000-0003-4989-145X Abstract: This essay proposes a comprehensive blueprint for the hylomorphic foundations of cosmology. The key philosophical explananda in cosmology are those dealing with global processes and structures, the regularity of global regularities, and the existence of the global as such. The possibility of elucidating these using alternatives to hylomorphism is outlined and difficulties with these alternatives are raised. Hylomorphism, by contrast, provides a sound philosophical ground for cosmology insofar as it leads to notions of cosmic essence, the unity of complex essences, and globally emergent properties. These are used as the basis to account for the aforementioned cosmological explananda and to resolve two problems in the philosophy of cosmology: the meta-law dilemma and the uniqueness of the universe. In summary, cosmology needs hylomorphism because it is able to ground cosmology’s efforts as a scientific inquiry. It can do so because hylomorphism philosophically accounts for changing substances and aggregates of substances, the various scales of law-governed behavior measured by the natures of those substances, and how those substances as parts relate to the universe as a whole. Keywords: hylomorphism, philosophy of cosmology, universe, laws, meta-law dilemma
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World enough and form: Why cosmology needs hylomorphism Attending to its recent developments, and taking a long view of the history of the discipline
during the twentieth century, it is no longer wise to ask whether modern cosmology has need of
philosophy and answer in the negative.1 Cosmology needs philosophy. More controversially,
however, cosmology needs a particular philosophy, the one that defends hylomorphism.
Hylomorphism is a general account of changing and changeable beings that appeals to a
complementary pair of explanatory principles of change: a determining form (morphe) and
determinable matter (hyle). In what follows, we offer a systematic blueprint for the hylomorphic
foundation of cosmology. This hylomorphic foundation grounds the possibility of global
regularities and structures, the regularity of global regularities, and the existence of the global as
such. We obtain these results by arguing that the universe is a whole whose members are
substances; that the universe at the global scale exhibits law-governed behaviors; and that the
universe is not merely an aggregate of substances but a system, a unity of order.
The original proponent of hylomorphism noted that in order to articulate a philosophical
topic well, the matter at hand must be clarified in itself, done so in a way “so as to solve the
difficulties” that belong to the topic, and lastly one must “[make] apparent the cause of the
perplexity and of the difficulties about it. For thus most beautifully would each thing be shown”
(Aristotle 2004; 211a7–12). We adopt this method in proposing an affirmative answer to our
question: Does cosmology need hylomorphism? We begin by introducing the idea of a
philosophy of nature (§1), and then the various explananda for which any proposed
philosophical foundation of cosmology must account, namely, permitting change and process in
1 Contra Dingle 1937; Hawking & Mlodinow 2012.
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the universe (§1.2), composition and structure in the universe (§1.3), and the resolution of two
key philosophical difficulties (§1.4). Next, we review various alternative proposals (§§2.1–2) to
the recently revived, Neo-Aristotelian school of thought (§2.3). We subsequently defend
hylomorphism itself (§3), along with two characteristics crucial to cosmology: the unity of
complex essences and global emergent properties (§3.4). We then employ these characteristics of
hylomorphism to account for the cosmological explananda (§4), and, lastly, to resolve two key
difficulties in the philosophy of cosmology: the meta-law dilemma and the uniqueness of the
universe (§5). We conclude (§6) that cosmology needs hylomorphism.
1 Explananda and difficulties
In this essay we assume that cosmology needs philosophy.2 However, an incompatible
variety of accounts have been offered as to which philosophy it needs.3 Generally, a distinction is
drawn between philosophical and empirical cosmology (Heller 2011, p. 165), or between
cosmologia and cosmology (Ellis 2017, pp. 3–4). This divides “metaphysical” or “philosophical”
issues from “scientific” problems and topics, a cut originating with Wolff and Baumgarten and
culminating with Kant, whose metaphysical system claimed transcendental priority over any
possible empirical inquiry into nature. This divide discounts the possibility of an empirically
grounded philosophy of nature that both contemplates the universe antecedent to any of the
specific natural sciences and yet is consequently refined by them. In what follows, by
2 See Rovelli 2018 for a general defense of this idea, and Ellis 2014 for specific defense.
3 See McMullin 1981, and his 1969 is a review of all possible philosophies of nature; Gale and
Urani 1993; Leslie 1999; Heller 2011; Ellis 2006, 2014, 2017; Unger and Smolin 2014, p. xvii.
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“philosophy of nature” or “natural philosophy” we intend such a viewpoint.4 It may help us
escape the needless dichotomy between mere philosophical reflection and sheer philosophical
imposition. Such a philosophy of nature—to bend the terms of Sellars (1963)—would include
the scientific image within the manifest image. It would do so if it were the definitive theory of
the manifest image insofar as the scientific image is dependent upon it (see Van Brakel 2013, p.
199).
What cosmology needs, as does science in general, is a philosophy of nature that grounds
micro-, meso-, and macroscopic scales in the universe as such. For our purposes, we will take
“macroscopic scales” to refer to cosmological scales; “microscopic scales” will keep its usual
sense. This renormalizing also recognizes mesoscopic individuals as given realities, such as
human beings or other animals and things in common experience. Based upon this “middle
scale” one may proceed to analyze either their parts at microscopic scales or to their collections
at globally macroscopic scales.5 Thus, the mesoscopic scale includes paradigmatic examples of
substances; the microscopic (cellular or atomic) and macroscopic (cosmic) scales contain mostly
parts of substances and aggregates or systems of substances, respectively.6 Keeping in mind the
distinction between the manifest and the scientific image, a philosophy of nature must begin with
4 We would thus distinguish “philosophy of nature” from “metaphysics” or “first philosophy,” as
did Aristotle (see Metaphysics, VI.1, 1026a27–32), although such epistemological bookkeeping
need not be accepted by readers in order to follow or accept our arguments.
5 See Tahko 2017; Oderberg 2017, p. 218.
6 Exceptions at the microscopic scale usually include unicellular organism and free atoms,
although the latter are debated by hylomorphists as instances of substances in their own right.
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the mesoscopic scale, since it is the most familiar to us at first (Aristotle 2004, 184a16–18).
What is the best natural philosophy at this “middle” scale?7 Historically, hylomorphism claims
this title. Hylomorphism’s self-referential coherence also recommends it. The true philosophy of
nature cannot propose principles that eliminate the philosopher who proposes the theory; for
instance, a sound philosophy of cosmology must be self-referentially compatible with the
thinking cosmologist (Ellis 2016, p. 29), who, on a hylomorphic account, exists at the
existentially familiar, mesoscopic scale. Since it begins from our metaphysical neighborhood, the
hylomorphic analysis requires a hierarchy of applicability so as to coherently ground all scales of
natural scientific reflection. It begins in the mesoscopic but must end in scales beyond without
reduction or elimination. We aim to apply it on the global scale. Indeed, to show its complete
worth, hylomorphism must go global. Will hylomorphism yield philosophical advantages for
cosmology?8 To prepare our answer, we articulate in the remainder of this section the various
philosophical marks that any philosophy of cosmology must meet.
1.1. The philosophical explananda
We begin by defending the basis for these explananda. As a science, cosmology has a
7 For recent work on this philosophy of the “middle-sized” or “ordinary” object; see Thomasson
2007, Van Brakel 2013, Boulter 2013, Needham 2017.
8 The literature on hylomorphism is vast; for the general background to our approach, consider
Maritain 1940, 1951, 1955; De Koninck 1959, 1961, 1964, 2008, 2009; Wallace 1996. Brague
2015, p. 37, expresses our concern: “I take here the word ‘cosmology’ in the meaning that is
suggested by its etymology: a logos about the kosmos. Not a description, but some sort of
account, an attempt at making sense of it, at deciphering its meaning.”
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specific subject, or that about which it is concerned, and argues for various properties of this
subject, thereby constituting the object of cosmology, that is, the subject with properties proven
of it. The mode of cosmology’s argumentation is empirical and physico-mathematical, and its
conclusions are argued to with probability. This schema descends from the Aristotelian-
Thomistic tradition of the logic of scientific inquiry and is useful for our purposes.9
The subject of cosmology is the universe: “Cosmology is the study of the large-scale
structure of the Universe, where ‘the Universe’ means all that exists in a physical sense” (Ellis
2006, p. 1183). The physical universe must be distinguished from the observable universe, for
our observational horizon is limited in various ways (ultimately by the last scattering surface; see
Ellis 2014, p. 8). However, as even a medieval could recognize, one cannot say without
qualification that cosmology studies “all that exists in a physical sense,” for this does not
distinguish it from the other sciences, such as physics or chemistry. Aquinas’s medieval view
specified that cosmology studies mutable beings insofar as they constitute those parts of the
universe having natural positions or places, which places determine all possible local motions
belonging to the elemental, fundamental natures.10 Ellis provides the modern specification: large-
scale structure. This “structure” is intended to pick out the law-governed, spatiotemporal
behavior, interaction, and formations of all mass-energy through gravitational forces and the
cosmological constant. Hawley and Holcomb provide another specification: “We restrict our
9 On the schema itself, see Aristotle 2014, Posterior Analytics, I.6, 75a29–37; Aquinas 1958,
1989; Maritain 1951; De Koninck 1957. To fill out this schema, we consulted Whitrow 1959,
Tolman 1987, Harrison 2000, Hawley and Holcomb 2005, and Ellis 2006, 2014, 2017.
10 See Aquinas 1886, In De Caelo, lib. 1, lect. 1, nn. 4–5.
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definition of cosmology to the study of the formation, structure, and evolution of the universe as
a whole” (2005, p. 5). These specifications assume that “the Universe” is a sufficiently stable
background concept (a background assumption that is no longer unproblematic, with no small
thanks due to Kant; see McMullin 1981, pp. 177–78). Consequently, cosmologists speak of
“model universes” as their subject (Whitrow 1959, p. 98; Harrison 2000, pp. 13–15). We
conclude, for our purposes, that cosmology’s subject is all physical objects, or the universe,
insofar as it exhibits law-governed behavior, particularly gravitational interaction and the
formation of structures at global spatiotemporal scales, captured in model universes. By “global
scales,” we mean those commensurate to the universe, which cosmology assumes to exist. Since
no science can prove the existence and nature of its own subject, defending the coherence of this
assumption is one clear task of the philosophy of cosmology.
The object of cosmology is constituted by cosmologists when they argue for what is true or
probably true about the universe as their subject. In order to do so, they make various prior
assumptions that yield theoretical outcomes (models), which are used to interpret a data-set of
observations. The prior assumptions include, for instance, items taken as established by particle
physics, general relativity, chemistry, and various scientific practices (e.g., spectroscopy). The
cosmological models predict or explain observable astronomical phenomena (e.g., elemental
abundance, cosmic background radiation, the Hubble constant). The standard model of
cosmology allows cosmologists to make probable truth claims about the universe: its age,
development, structure, its parts and their historical characteristics, its spacetime geometry, and
its possible natural fates. Such claims are limited by the nature of the physico-mathematical
method. These limitations lend a dialectical status to the standard model (Ellis 2017, p. 22). This
status of probable truth is in no small part due to the inquiry’s subject:
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The underlying basic problem in studying cosmology is the uniqueness of
the universe. There is only one object to look at, and no similar object11 to
compare it with. Also there is no chance to rerun it in an experiment. This
is what makes cosmology unique as a science . . . . It is a unique historical
science, where no direct experiments are possible on the object being
investigated as a whole (even though many are possible on parts or aspects
of the whole). (Ellis 2014, p. 6)
Any philosophy of cosmology must be able to ground the features of both the subject and object
of cosmology, including its status as “a unique historical science.” By “grounding” we mean
providing an account through principles that make possible the truth of scientific explanations.12
In the next two subsections, we detail our explananda based on this subject–object schema.
1.2. Change & being
A changing being is something whose motion is from a start to an end: its being is whence-
whither. A moving thing also implicates a subject and a succession of states (possibly a
continuum of states). Most philosophical accounts of motion take this basic structure for granted.
Thus, we can use it without bias to develop certain explananda of cosmology: law-governed
behavior, the conditions of this behavior, and the permitted kinds of behavior.
First, a philosophy of cosmology must provide a foundation for discussing laws at a global
scale that capture the behavior of parts of the universe. Cosmological processes have spatial and
11 Note that Ellis uses “object” here in a way that it names the “subject” of cosmology. An object
of our experience can also be the subject of an inquiry.
12 Compare Pruss 2013, pp. 120–21, 132. We further clarify “grounding” in §2.
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temporal features, are thermodynamically and temporally asymmetric, and permit mathematical
description. Second, the existence of global initial conditions and constants must be given some
account. These initial conditions are necessary in order to give a physical meaning to the
mathematical models of cosmology. They also represent characteristics of the actually observed
universe that discriminate between alternative model universes. Third, the kinds of processes that
are permitted at cosmological scales and their connection with other physical processes must be
given some account. This primarily includes processes that form the components of the universe
(Big Bang nucleosynthesis and the formation of the principal cosmological objects—nebulae,
stars, planets, star clusters, galaxies, and galactic superclusters).
1.3. Composition & structure
Mutable beings also exhibit composition at a time (synchronically) as opposed to over a time
(diachronically). Various well-known philosophical problems concern the composition of
material objects. Here, we can apply the notions of part-whole composition and the aggregation
of individuals to further articulate the explananda of cosmology.
First, the philosophy of cosmology must be compatible with familiar kinds, the ordinary
objects of everyday experience (e.g., cosmologists). Second, it must provide a way to see the
existence and relationships between local and global structure of physical objects in the cosmos,
for cosmology is a theory of the whole that includes all smaller scales as parts in some way and
permits their possibility. Third, it must allow for a natural understanding of the kinds of objects
permitted in the universe and the makeup of those objects (e.g., galaxies with a certain hydrogen
abundance). This is related to the second requirement insofar as cosmology studies aggregates of
individuals with ultimate constituents or material parts. Fourth, the sought-after basis must also
generally sustain the possibility of spacetime, even apart from specific interpretations of the
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mathematical formalism of special and general relativity, and it must also sustain the possibility
of this universe having a particular spacetime structure (e.g., globally flat or curved). Clearly this
overlaps topics from §1.2. However, if space and time are ontologically posterior to the
synchronic structure of objects, then the problem of spatiotemporal structure belongs in this
category.
The topics arising from the diachronic character of mutable being comprise a first area where
hylomorphism can ground cosmology (§1.2). The second area is the synchronic features of
mutable being (§1.3). Grounding both would provide us with the first overall result in the
philosophy of cosmology: an account of the existence of global regularities and structures.
1.4. Two key philosophical difficulties
The following two difficulties are some of the specifically philosophical problems that arise
in cosmology. They are philosophical since they concern cosmology’s presupposed
methodology, epistemology, or ontology. While these two are not the only such difficulties, they
are central and illustrative test cases.13 Can hylomorphism successfully address them?
The first problem concerns the regularity of global regularities. Generally, the possibility of a
change of the laws of the universe is recognized by various cosmologists.14 This problem leads to
the meta-law dilemma articulated by Roberto Unger and Lee Smolin (2014). They defend
“temporal naturalism,” the view that what exists does so by being contained within time. Nature
is a “historic” or time-soaked reality; there is no realm of separate, atemporal laws governing it.
13 Another issue that we do not have space to consider in this essay is the question of how
mathematics is applicable to the study of nature. However, see the final argument in §4.2.
14 See Bondi 1990, p. 192 and Gale 2011; Barrow and Tipler 1988, p. 255–56.
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If everything that exists is subject to change in time, this includes the laws of nature, whether
within the history of a given universe or through the succession of “generations” of universes.
Now suppose, on the one hand, “that the change of laws of nature is itself governed by laws:
higher-order laws or meta-laws. Then the problem of the historicity of nature and of its
regularities will simply recur at that higher level” (ibid., p. 275). That is, the regularity of global
regularities would defeat their temporal naturalism. However, if there are no higher-order laws
governing the change of law-governed regimes, then “it seems that [this change of law-regimes]
is uncaused, which is to say arbitrary or at least without explanation, whether deterministic or
probabilistic. Then indeed the idea of a history of the universe would have driven us to
explanatory nihilism” (ibid.). That is, in the absence of using laws as our sources of explanation
in science, the alternative in the meta-law dilemma seems to be scientific irrationality. Is
hylomorphism able to escape the meta-law dilemma and ground the regularity of global
regularities?
The second problem concerns the existence of the global as such. Typically discussed in
terms of a “multiverse,” this topic impinges as much upon the models of the universe as it does
the nature of the cosmologist’s presuppositions about the existing Universe.15 We leave to one
side the “many worlds” views deriving from metaphysical interpretations of modality and
possible worlds.16 A multiverse or “many worlds” is also implicated in the Everettian
interpretation of quantum mechanics (see Wallace 2012), which we likewise leave aside.17 The
15 See Ellis 2011, 2014; Kragh 2009; Stoeger et al., 2004.
16 See Oderberg 2009 for a convincing critique.
17 The Everettian thesis does not add anything new to cosmological multiverses as such, but
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multiverse as a cosmological topic is motivated by various scientific problems (e.g., how to
explain the precise values of cosmological constants that permit living beings). Objections are
raised for and against the uniqueness or multiplicity of the universe based on whether notions of
“laws” or “probability,” which typically concern sets of individuals, are applicable to the
universe as a whole.18 The theoretical elaboration of cosmological multiverses is also required by
the mathematical models of the inflationary universe hypothesis (see Steinhardt 2011; Guth and
Steinhardt 1984). Following Ellis et al. 2004 (pp. 921–22), we will distinguish between
“universes” that are causally connected (even if only in the past) from those which are causally
disconnected. The latter we will call a para-universe. The former is still one universe, even if it
is a certain ensemble or a multi-domain universe, “the one unique connected existing spacetime
of which our observed expanding cosmological domain is a part” (ibid., p. 921).19 Can
hylomorphism successfully address this topic, and ground the global as such?
2 Alternatives
Alternative positions in the philosophy of science are sometimes schematized in terms of realists
or anti-realists (Chakravartty 2007, p. 10). Others divide the territory between Humeans, semi-
Humeans, and anti-Humeans (Bird 2010, p. 1–2), or equivalently, between regularity
theorists/Humeans, nomic necessitarians/Platonists, and dispositionalists/Aristotelians; (B. Ellis
2002, pp. 1–2; Dumsday 2013, p. 143). Others use the vantage point of the problem of universals
merely extends existing ones into various quantum branches (Tegmark 2003).
18 See Ellis 2014; Unger and Smolin 2014, Part I, ch. 1, and Part II, ch. 2.
19 One subsequently asks, qua cosmologist, how a multi-domain model is testable.
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(Peterson 1996). However, these contemporary maps are palimpsests over an older schema
(Aristotle 2004, 184b14–20). Aristotle divided approaches with these questions: Do you say that
the principles of nature one or many? If they are many, are they finite or infinite in number?20
By “principle” we have in mind an analogously applicable notion. A principle is some thing
in reality or in our knowledge (e.g., a physical force, a cause, an organic power, a moral agent, a
premise, an axiom, an argument) standing first in an order of responsibility for the existence or
knowledge of others. It is related to the idea of “ground.”
Principle: that first thing from which a thing either exists, comes to be, or is known (see
Aristotle, Metaphysics, V.1, 1013a17–20).
To Ground: to be or act as a principle of some thing’s being or being known.
A principle of nature, therefore, is an origin of being, becoming, and knowledge with reference
to the natural world. Natural principles as grounds are of key concern to the philosophical
foundation of the sciences.
We now review alternatives for a philosophy of cosmology. While our presentation does not
20 By using this schema we not only gain a broader view of possible alternatives but can usefully
juxtapose contemporary views with older traditions. While Aristotle’s schema does not, in
places, map neatly onto contemporary ideas, reviving his division and seeing its plausibility will
complement our revival and defense of the division’s original theoretical target: hylomorphism.
Besides, the usefulness of returning to the Greeks for inspiration has been noted before: “In
probing the foundations of any domain of contemporary problems—e.g., of physics—one
discovers the same structures that the Greek philosophers discovered long ago, if from a different
angle” (Weizsäcker 2014, p. 136).
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claim either to do justice to all the substantial details of these alternatives or to refute them
definitively, certain difficulties will be raised with each so as to highlight the possible advantages
of a complete hylomorphic foundation for cosmology, whose blueprint is our main concern.
2.1. The new Pre-Socratics?
We begin with positions that advocate one or indefinitely many principles of nature. Views
based upon the “block universe,” a seemingly natural interpretation of the mathematics of
relativity theory, or the monism of Jonathan Schaffer illustrate the former view. Unger and
Smolin are illustrative heirs apparent of the latter view.
The new Parmenideans typically use relativity theory to defend a version of spacetime
monism: the universe is fundamentally one thing due to the unified nature of spacetime (Schaffer
2009, 2013). However, strong cases have been made that the block-universe view is undermined
by self-referential difficulties if one denies the reality of the passage of time (e.g., Feser 2017,
pp. 38–40). Schaffer’s own “priority monism”—his attempt to avoid “existence monism” by not
denying that there are other “things” in the world (like you and me), and asserting that these
things are instead neither fundamental nor substances—might indirectly collapse into existence
monism if arguments in Tahko 2017 are sound. If it does, this new monism, just like its old
counterpart, would fail to permit without eliminativism the existence of global regularities and
structures at the micro-, meso-, and macroscopic levels.
Today’s new Heracliteans continue the tradition of process metaphysics that draws its
inspiration from Heraclitus’ unique river; modern variants of such ontologies have been
proposed by Hegel, Whitehead, and Peirce. Unger and Smolin (2014) defend a “proto-ontology,”
that is, not “an ontology in the making” (ibid., p. 239) but a rejection of “the project of
establishing any view that represents the world to have an abiding structure, complete with a list
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of the kinds of things that there are and of the ways in which they eternally interact” (ibid., p.
240). Their proto-ontology only assumes reality with plurality. The first means that what exists
cannot come from nothing (the non-real), and the second places “otherness” in nature such that it
is a principle of change and consequently of time, “a susceptibility to variation or differentiation
within the one: the otherwise single and uniform reality” (ibid., p. 241). This “susceptibility” is
fundamental and rooted in every aspect of what could be, consonant with their temporal
naturalism. In such a universe, the only constant is change; all forms or types are impermanent.
Nature’s principles are therefore indefinite. The meta-law dilemma is a consequence of this
proto-ontology.
2.2. Hume? Plato?
Contemporary philosophies that advocate a finite plurality of principles are, generally, three.
As mentioned above, the typical division among these alternatives is between the regularity
view, the nomic necessitation view, and the dispositionalist view. These have been advanced
based upon overarching concerns to account for the laws of nature used by modern science. The
first two situate the ground of nature’s laws extrinsically to the behaviors and structures in the
universe (the grounds proposed are not constitutive of the very being of the behaviors and
structures).21 The third view situates the ground of laws intrinsically in relation to those
behaviors and structures (the ground does constitute their being in some way).
The first view is the Neo-Humean or regularity view of the laws of nature.22 This view
maintains that “laws are regularities that fit into or may be derived from the optimal
21 See Heil 2017; Dumsday 2012; Bird 2010, pp. vii, 97; Feser 2014, pp. 69–70.
22 See Lewis 1983, 1987, 1994, 2001 [1973].
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systematization of the facts concerning individual things” (Bird 2007, p. 1). This is typically
paired with both recombination and Humean supervenience.23 Recombination maintains that
there are no objective modal connections between existing events in the universe; there is no
“inner character” of one event that makes a subsequent event possible (with probability or
necessity). Humean supervenience maintains that laws bear a supervenience relation to the
mosaic of all such events (which events are usually conceived of in terms of spacetime points). If
the regularities of the events differ, so will the laws, and thus the laws are said to supervene upon
the mosaic. The laws of nature are our epistemically efficient, factual generalizations about
nature and contingently categorical truths.
The second view is a Platonic approach to nature’s laws, which is not uncommon among
cosmologists.24 This view is frequently assimilated, as the more general case, to the nomic
necessitation view.25 (This latter view is superficially similar to ontic structural realism, or OSR;
see French 2014, chs. 5 and 8–9.26) Nomic necessitation generally maintains that something
23 See Harré and Madden 1975; Dumsday 2012; French 2014, p. 232; Simpson 2017, p. 125.
24 Prominent proponents include Roger Penrose or George Ellis.
25 See Dretske 1977; Tooley 1977. Armstrong 1983, 1997, claims to avoid the charge of
Platonism; see Carroll 1994, Appendix A; Dumsday 2013, p. 143; Mumford 2004, p. 91; at least
Bird 2010, pp. 51–55, and Feser 2014 p. 70, characterize Armstrong’s view about universals as
closer to the Aristotelian line. However, insofar as they all fall prey to the third-man objection
leveled against Platonism, based upon second-order universals, we consider these views together.
26 As a basis for the ontological interpretation of relativity theory and thus a possible
philosophical ground for cosmology, OSR is critiqued—effectively, in our view—by Feser 2017,
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more must be said about the laws of nature beyond the claims of the regularity theory: “For it to
be a law that an F is a G, it must be necessary that an F is a G, in some sense of ‘necessary’”
(Armstrong 1983, p. 71). The way to obtain such necessity is by appealing to what ‘F’ and ‘G’
are. These quiddities of ‘F’ and ‘G’ are universals instantiated in states of affairs; the laws of
nature are second-order universal relations between these first-order universals, upon which the
second-order relation confers necessity. This nomic necessitation relation is a fundamental,
inexplicable reality.27 Still, these laws are contingent because the second-order links between
first-order universals could have received a different cosmological distribution.
Both of these views have been widely criticized. We will only note certain difficulties
pertinent to the philosophy of cosmology. These views have in common the fact that they tend to
divorce being from doing. In this respect, both views are modern descendants of occasionalism
about the powers and natures of things.28 They claim agere non sequitur esse—manifested
operations do not follow upon the inner being of a thing. This makes either view prima facie
difficult to square with the demands of our cosmological explananda, since the development and
existence of interconnected scales is crucial to that scientific inquiry. The being and activity of
one scale has the power to affect the very being and activity of things at another scale: e.g.,
certain distributions of matter and elemental abundances are required for the emergence of life,
and so evolutionary processes would be dependent upon cosmological processes.
pp. 47–50. However, since Feser limits himself to special relativity, his critique is also limited.
We also must leave aside OSR in this essay, since we do not have the space to do it justice.
27 See Armstrong 1983, pp. 85–86.
28 Similar points are made by Bird 2010, pp. vii, 47, and see especially Heil 2017.
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This general cosmological difficulty can be specified. The Neo-Humean’s use of
recombination requires “that the notion of a change in the course of nature is not self-
contradictory” (Harré and Madden 1975, p. 44). Yet this claim depends, in part, upon a
conceptually atomized redescription of events that highlights contingent connections and ignores
necessary conceptual links discovered in scientific inquiry (ibid., pp. 44–49). Furthermore, if one
adopts the thesis of supervenience, one might undermine the unity to the physical universe to
which empirical discoveries of cosmologists attest. If so, the Neo-Humean seemingly has no
non-epiphenomenalistic account of the global as such to offer to the cosmologist.29
The particular difficulty for the nomic necessitarian’s view parallels ancient objections.30 If
the laws of nature are second-order universals that ground a relation of necessitation between
first-order universals, what necessitates the relation of the second-order universals to the first
such that this association is itself not a merely contingent regularity? If it is due to a third-order
relation of necessitation, a recursion problem results.31 Furthermore, if the universe, the global as
such, is a state of affairs whose unity is constituted from a hierarchy of such higher-order
universal relations that constitute the most global universal laws (Armstrong 1997, p. 267), and
yet the ground of this unity is susceptible to an infinite regress, then the universe which
cosmologists study is, ultimately, not unified. The universe would be a loose aggregate, only
29 See Harré and Madden 1975, p. 80.
30 See Plato, Parmenides 132a–b; Aristotle, Metaphysics 990b15, 1059b5–10. Hence, the
problem is generalizable to other versions of Platonism. The other key difficulty is Mumford’s
“Central Dilemma”; see Mumford 2004, pp. 143–45; Dumsday 2012, p. 116.
31 Bird 2010, p. 94.
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existing in astronomical appearances. The common lesson from these arguments is that a causal
texture to the universe must come from within if the universe is to be and to behave as a
universe: agere sequitur esse.
2.3. Powers, dispositions, and the new Aristotelianism
As a large family of views, dispositionalism situates the ground of laws intrinsically in
things. They do so by maintaining that at least some properties are dispositional: things are
disposed to, prone to, or ordered to certain manifestations, behaviors, or acts given certain
conditions or stimuli. “Potency” and “power” are reintroduced into nature. Views about powers
diverge when asked about how they ground laws. Proponents generally agree that powers
underlie the laws of nature but differ on whether one needs laws at all. For instance, Bird defends
the existence and explanatory significance of the laws of nature, while Mumford holds that one
needs only powers and can dispense with laws; others maintain a middle ground.32
Akin to dispositionalism, hylomorphism arises as an analysis of the coming to be and being
of physical objects in terms of matter and form. In dispositionalist terms, “form” generally
designates a constitutive principle of the actual manifestation of beings, whereas “matter”
designates the power or disposition of things. However, hylomorphism is not coextensive with
dispositionalism, for it usually entails the defense of a unifying and essential ground of a thing’s
dispositional properties: substantial form. Furthermore, contemporary hylomorphism is a variety
show, ranging between “staunch” and “faint-hearted” versions (Koons 2014). The “faint-
hearted” versions selectively or completely deny the following: a power ontology, a sparse view
of both fundamental entities and powers, and the existence of fundamental essences and
32 See Groff and Greco 2013, p. 3; see also French 2014, p. 248ff.
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properties. Staunch hylomorphism defends all three views. Cosmology needs a version of
“staunch” hylomorphism, which Koons explains as follows:
To differentiate hylomorphism from materialism, staunch hylomorphists
seek to identify a sparse collection of fundamental composite entities or
substances, with enough sparseness to rule out coincident substances
altogether. Given a powers account of causality, a sparse theory of
fundamental things corresponds to a sparse theory of powers and power-
bearers. The crucial question for staunch hylomorphists is this: What is the
relation between the powers of a whole substance and the powers of its
proper parts? (ibid., p. 157)
Koons’s question enables one to approach issues related to a hylomorphic account of material
composition (e.g., the chemical parts of substances, see Koons 2018b). We are looking for the
hylomorphic foundation of cosmology and thus towards an opposing hierarchy of scale, to the
globally macroscopic. Therefore, our crucial question is correspondingly different: What is the
relation between the powers of a whole substance and the properties of the aggregates or systems
of which it is a member? It naturally leads to questions such as the following: Does the universe
as such have a “world disposition” or “power”? Why can an aggregation of individual substances
be and be studied as a universe? Such questions about the universe are of central importance to
any dispositionalist or hylomorphic philosophy of cosmology.
3 Hylomorphism
We have reviewed the various alternatives and provided preliminary reasons to prefer
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hylomorphism. More would have to be said to adequately refute the alternatives.33 In the interest
of presenting a positive account, we turn to a defense of hylomorphism.
3.1. Motivating hylomorphism
There are four general motivational accounts for hylomorphism. Each is an answer to a
philosophical problem. First, there is the problem of change, also known as the Eleatic paradox
(Aristotle 2004, 191a23–34). Second, and closely related to the first, is the problem of diachronic
unity (e.g., the Ship of Theseus). Can one thing both change over time and remain the same?
Third, we have problems of synchronic unity or composition. If a substance cannot be made out
of substances, then in what sense is one material whole composed out of material parts differing
in kind? Fourth, there is the problem of the one and the many, under which we include the
problem of universals and of the numerical differentiation of things the same in kind.34
Of these four, the first is the most fundamental for two reasons. First, the Eleatic paradox is
naturally the first paradox among them all. The principle of non-contradiction requires the self-
consistency of our thoughts about reality, and yet we sensibly experience beings that change,
which seemingly are what they are not. The Eleatic paradox thus arranges the mind and the
senses, our basic cognitive powers, against each other. For this reason, Parmenides’ famous
poem depicts two paths of thought.35 Therefore, this problem must be addressed first in natural
philosophy. Consequently, and second, the solution to the Eleatic paradox governs the solution to
33 In particular, the hylomorphist must address concerns of dispositional monism (Bird 2010) or
other versions of hylomorphism; for such replies, see Oderberg 2011, 2013, and Koons 2014.
34 Koons 2018a helpfully discusses the last three issues.
35 See Parmenides, Fragment DK B2.
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the other three problems and not vice-versa.
3.2. Being in time
We adopt a temporal approach to the Eleatic paradox and motivate hylomorphism from the
reality of time or duration. In this sense, we take Heraclitus as our interlocutor and not
Parmenides. We stipulate, based on experience, a sum-total or aggregate of enduring objects, or
individuals that exist in time. This duration includes all manners of their change.36
Implicit in this notion is the requirement for successive otherness. If the objects enduring
through time did not do so by successively exhibiting one state that differs from another, they
would neither be changing nor enduring through time, which is against the hypothesis.
Furthermore, this succession implies the notion of order, where one state follows after another in
sequence. Here we also require a minimal sort of modality: not just anything could follow
anything. This is again consonant with experience.37
Now, required by the existential duration of things exhibiting otherness is a subject of such
otherness. That is, we experience and say that various things are changing. If this were not the
case, no thing would be changing, which is against the hypothesis. This invokes the principle of
non-contradiction and requires the truth of a predicate ontology: the ways of being are
proportioned to ways of being said.38
36 To this a Heraclitean would agree, but object to any implied permanence of those individuals.
37 It would also be granted by Heraclitus, who posits a logos to the flux of being.
38 Here the Heraclitean parts company with us; however, see Aristotle, Metaphysics IV.3–4 and
Plato 1997, Cratylus, 439c–440e and 439d on the various problems that result. See Aertsen 1987,
pp. 16–31, on the medieval notion of the katallel structure of being, summarized in lapidary
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Finally, the successive existential duration of things subject to change must be a continuous
existence. That is, the duration of things has no gaps. If there were gaps in the existence of things
subject to duration and change, there would be no continuity of subjects, and thus no things
would be changing, which is against the implication of the hypothesis just given.
Here the paradox arises.39 If changing being implies a subject that is successively other, then
how does it remain the same across each state of successive otherness? If it is not the same
across each state, then it does not succeed itself and its existence is not continuous. The notion of
a thing subject to change appears to be contradictory: “Mobile being must be a being which
changes and which does not change.”40 The nature of a changing subject has existence and at the
same time it loses its existence.
3.3. Hylomorphism, briefly stated
The resolution to this paradox of changing beings in time is a distinction. It divides the nature
or essence of that which endures.41 This essence must be determinable by successive states. This
essence must also be determinate to being what it is, and thus continuously remaining the same
kind of thing (unless radical change destroys it). The principle of determinability or
indetermination we call matter; the principle of determination is form. Thus, the changing
subject has a determinate existence which is, in another respect, open to what it lacks due to its
fashion by Aquinas 1884, In Phys., III. 5, n. 15: “The modes of being are proportional to the
modes of predicating.” (Translations of Aquinas our own unless indicated.)
39 See De Koninck 2008, p. 259.
40 Ibid.
41 The following line of argument follows De Koninck 2008, pp. 259–61.
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ability to be determined otherwise at future times. Hence, Aristotle and Aquinas list the
fundamental principles of nature as form (determination), matter (indetermination), and privation
(lack).
Since our initial stipulation ranged in general over all possible types of change in the total
aggregate of changing things, our notions of matter and form are proportionately vague.
Therefore, they would have to be specified through more detailed arguments. Indeed, these
notions of matter and form must be specified through accounts of accidental and putatively
substantial changes, accounts of diachronic and synchronic unity, and an account of numerical
individuation and the possibility of universal concepts of common natures, to say nothing of
analogous applications of hylomorphic principles to determinate scientific scales of inquiry.
We will call this hylomorphic nature or essence—that intrinsic principle by which something
subsists in being— a “cosmic essence” (CE) both to indicate that we aim to draw out how it
grounds a philosophy of cosmology and because, due to the original ambit of the problem, CE is
compatible prima facie with a whole cosmos subject to change. We note a few basics about CE.
First, note that CE contradicts the Neo-Humean’s principle of recombination (for form is
determinately such over time), the Platonist’s extrinsicism (for CE is internal to a substance), and
the monist’s denial of distinct substances. Note also that CE is complex by having parts that are
ordered to each other as correlative principles of change. These parts thus compose the nature of
a substance insofar as nature is a principle of motion and stability or rest (Aristotle, Physics II.1).
This correlativity of form and matter also requires that the material part be pure indetermination
(otherwise it would be a principle of being determinately such, and not the possibility of any
state or manifestation). This material part must also be common to all mutable beings for the
same reason. The formal part, as correlative to that potency or determinability, actualizes or
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determines it to be such while not exhausting its potency to be otherwise. That is, the material
part of CE is indefinite in its potency, whereas the formal part is finite in its determination. We
define this notion as follows:
Cosmic Essence (CE): an essence that is composed of two parts, one part is a principle of
determination (form), and the other part is a principle of indetermination (matter);
termed “cosmic” because of its compatibility with a universal ambit of change.
We now articulate two key characteristics of CE.
3.4. Cosmologically crucial features of cosmic essences
The first characteristic of CE is its determination of a multiplicity of properties by one
essence. Traditionally, hylomorphism defends the idea that a nature can ground multiple
properties or types of behavior. Call this the idea of a unified complex essence (UCE).42 Both
common and scientific experience instructs us that different things are capable of sharing some
properties while differing in others. Some properties are distinct and yet necessarily linked (e.g.,
triangular area and a triangle’s angle measure), other distinct properties are contingently linked
(e.g., having a high temperature and being in a gas phase; social behavior and high cognitive
capacity), and some properties might be unique to a type (e.g., rationality). Furthermore,
assuming CE, empirical investigation discovers necessary relationships between properties.
Some forms of non-living or living being might uniquely have a property and yet share other
properties with nearly every other thing in the universe (e.g., being a gravitating object). By
contrast, the Parmenidean denies the existence of substances with distinct, ordered sets of
42 See also Oderberg 2007; Dumsday 2010; Gorman 2014.
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properties. Furthermore, a property might primarily characterize a physical being as unique to
that kind, while its other secondary, tertiary, etc., properties are common to other natures.43 So,
UCE permits an order amongst unified sets of properties; such unities and their mutual ordering
of properties (e.g., orders of dependency or correlative frequency) must be discovered through
empirical investigation. Having a multiplicity of properties allows one “to read off” different
domains of laws across the forms of different kinds of things insofar as some domains apply to
the commonly held properties whereas others focus on more idiosyncratic properties.44 Given
that substances exhibit such arrays of properties, we must infer that the formal part of CE is not
limited to determining only one type of property. We define UCE as follows:
Unified Complex Essence (UCE): a cosmic essence (CE) as the ground of a multiplicity of
properties (some possibly unique, others common to other substances), which all
belong to a substance, are as a set unified by form and made possible by matter, and
which are mutually ordered amongst themselves.
Form is at least minimally unified insofar as it is the truthmaker for this set of linked properties
(compare Dumsday 2010). However, we further stipulate a stronger, maximal unity: CE and
UCE require what was traditionally called the unicity of substantial form.45
43 See Aquinas 1884, In Phys., lib. 2, lect. 1, n. 5: “[Aristotle] adds primarily [to the definition of
nature] because nature, even as it is a principle of the motion of composite things, it is not such
first. Thus, that an animal falls down is not due to the nature of the animal as such, but due to the
nature of the predominant element.”
44 See Larenz 2013, p. 495–96.
45 This view claims that one substance has only one substantial form, not many. For various
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The second characteristic of CE, in conjunction with UCE, is that it makes possible global
emergent properties (GEP). These are properties of large-scale aggregates, in function of the
relatedness and coordination of individual substances. This is possible because CE is not the
cause of an independent, isolated substance, but joins substances as members to larger wholes if,
on UCE, one or many of its properties entail extrinsic relatedness to or determinability by other
things. GEP thus runs counter to the Neo-Humean view of supervenience at global scales; it also
agrees with critiques of the “pointilliste” grounding of global features upon a spacetime mosaic
of points (see Butterfield 2006a, 2006b, 2006c, 2011).46 GEP is also opposed to priority
monism’s view of the universe as the single, fundamental substance. GEP’s local-to-global
connection rooted in form is, like UCE, an old feature of the hylomorphic account: “Any
creature whatsoever subsists in its own being and has a form through which it is determined as to
its species and has an order to something else.”47 First, this connection is clear in instances of
natural environments or surroundings, where a thing can act and be acted upon by other things.
Second, GEP also permits physical systems (e.g., a system evolving thermodynamically) or
biological ones (ecosystems, adaptive niches). Third, among these properties, some might be so
common that they are common to all objects on a cosmological scale. Such maximally global
defenses, see Aquinas 1888, ST, Ia, q. 76, a. 4; 1918, ScG, II.58; also Feser 2014, p. 187ff.
46 However, the hylomorphist must have distinct views about the details; see fns. 48, 49.
47 Aquinas 1888, ST, Ia, q. 45, a. 7, c. (emphasis ours). According to Aquinas, this relationship
between forms eventually constitutes the form of the universe as a whole, including quotidian
cases: “A mouse is killed by a cat to preserve the good of the universe. For this is the order of the
universe, that one animal lives off another” (Aquinas 2018, Super Mat., X, lect. 2, n. 874).
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properties would not only belong to things in common but also be necessary conditions for
constituting a large-scale system of interacting objects (e.g., by being a gravitating object, by
being such as to permit interactions that exhibit the conservation of energy).48 Thus, GEP is also
compatible with the existence of global properties that are also conditions productive of “top-
down” effects, either those determining the context for local physical variables or those
determining the boundary conditions for isolated systems (see Ellis 2017, pp. 274–86). Finally,
GEP incorporates the insight that some aggregates are natural “systems,” true unities calling for
independent analysis (Clarke 2009; Juarez 2017, p. 11). We define GEP as follows:
Global Emergent Properties (GEP): large-scale properties, that is, properties of aggregates
or systems of substances, which properties are grounded locally due to CE and arise
globally due to mutual relations or causal interactions on UCE.
GEP, then, is the local grounding, by CE and UCE, of global-scale properties. How exactly GEP
obtains in the universe is an empirical question, one that the various sciences investigate. It is
also a separate question whether CE and UCE are necessary and sufficient conditions to explain
GEP or whether they are merely necessary. That is, it is possible that GEP requires further causes
48 As critics and proponents of dispositionalism have noted, conservations laws “deserve special
attention and, in any case, extra work is needed for their accommodation within the context of
[dispositionalism]” (Livanios 2018, p. 70; see also B. Ellis 2001, pp. 205, 249; Bird 2007, pp.
213–215). Since GEP permits the local ontology of hylomorphic substances to be determinable
in part by global conditions, conservations principles as features of the coordinated interactivity
of physical objects in the cosmos can be accommodated. We plan a separate defense to show in
detail how hylomorphism meshes with least action and conservation principles.
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for its own sufficient account (see the end of §5.2 and §6).
4 Grounding modern cosmology through hylomorphism
Hylomorphism, using CE, UCE, and GEP, provides us with a way to meet the cosmological
explananda. First, however, the relationship between hylomorphism and motion must be clearly
established. CE-style hylomorphism leads one, with little trouble, to Aristotle’s definition of
motion, or, “the actuality of what exists in potency, as such” (2004, 201a11). This definition
requires that motion possess a twofold order between a disposition and a manifestation, or the
potency and act intended by the definition. Consider a lukewarm object that is disposed to
becoming hot. That object is being heated, or is in motion, only insofar as (i) the present act
(manifestation) of lukewarmness has an order to a prior potency (disposition) already realized
and insofar as (ii) its potency to be hot (a disposition) has a present order to the act
(manifestation) of heat not yet gained. In other words, the present act of lukewarmness does not
manifest the correlative potency to be lukewarm as such, nor does the present potency have an
order to the present act of being lukewarm as such. Once again:
An imperfect act fulfills the definition of motion both insofar as it is
compared to a further act as a potency and insofar as it is compared to
something imperfect as an act. Thus, motion is neither a potency existing
in potency, nor is it an act existing in act, but it is an act existing in
potency, (i) such that “act” designates the order of [the mobile] thing to a
prior potency, and (ii) such that “existing in potency” designates its order
to a further act. (Aquinas 1884, In Phys., lib. 3, lect. 2, n. 3; our numbers)
The temporal structure of motion is readily apparent in this twofold order: the past arises from “a
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prior potency” now manifested, and the future from “a further act” yet to be realized. Thus, not
only motion but temporal structure is naturally recovered by this analysis. Furthermore, instead
of considering “a motion” as nothing beyond what supervenes on “the occupation” of the moving
object at points of space and at moments in time, the hylomorphist grants a unity to a motion
between its beginning and end. The hylomorphic account thus defends the continuity of motion
(or at least its virtual continuity, in view of quantum mechanics), contrary to “at-at” analyses of
motion (classically defended by Bertrand Russell and implicit in the pointillisme of Lewis; see,
respectively, McCoy 2018 and Butterfield 2006a, 2006b, 2006c, 2011).49
How will this general hylomorphic theory of motion be of service to cosmology?50 By UCE,
each moving object can possess a range of types of motions as properties. By GEP, it is possible
49 A development of the hylomorphic account of the physical continuum, the continuity of
motion, and its implications for endurantism and perdurantism is beyond the scope of this essay;
on this Aristotelian theory of the continuum, see Hassing 1991, White 1992, and Hellman and
Shapiro 2018.
50 We note below where our hylomorphic account must be articulated with more precision so as
to incorporate, into a broadly Neo-Aristotelian framework, the various foundational concepts and
current difficulties of classical, relativistic, and quantum mechanics. Regarding the
epistemological requirements of this framework, see Cartwright 1989, 1999, and Lanao and Teh
2017. Cartwright (1989, p. 198–99) acknowledges the “traditional metaphysical issues” related
to abstraction and the problem of universals at play here; in this respect it is useful to consider
whether older theories of abstraction can apply in these contemporary contexts; see Maritain
1995, De Koninck 1957, and Brungardt 2016, 2018.
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that this kind-infused range is global or systematic, although whether or not this obtains and how
is something that requires empirical investigation.
4.1. Change & being in the universe
We now turn to discuss how hylomorphism grounds change and being in cosmology
(outlined in §1.2). First, something must ground cosmology’s discussion of laws insofar as these
imply time-bound behavior. Now, hylomorphism grounds the explanation of regular, time-bound
behaviors, and what grounds such behaviors also grounds laws. Hylomorphism can provide such
a ground through CE and UCE. First, CE, on the side of form, is a principle that determines a
subject’s mobility. An object’s nature is such a ground insofar as the nature is a principle or
ontological measure of the object’s motion.51 This determination of a mobile subject allows for
its various natural motions, which motions in turn possess a temporal structure. Second, UCE
implies that a given form may have a range of ways of determining the behavior of an object. An
object could therefore exhibit gravitating, thermodynamic, chemical, or biological modes of
behavior. Our interest is preeminently with laws of a global scale (see §5.2). Hylomorphism
grounds laws, therefore, insofar as the unified complexity of the formal principle of CE grounds
modes of determinate behavior over time.
Second, the philosophy of cosmology must ground the existence of global initial conditions
and constants. Now, hylomorphism grounds the possibility of individualized and particularized
conditions of motion. What grounds such a possibility, however, also grounds the existence of
initial conditions and constants. This ground arises from CE and GEP. First, CE on the side of
matter entails the individuality of those things subject to motion. That is, changing things must
51 De Koninck 2008, pp. 377–78.
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possess a particularized set of properties to be in motion: a here, a now, a being situated or
positioned in such and such a manner, being arranged with a certain density, etc. Second, GEP
permits properties of individual mobile subjects to exhibit global coordination with particular
characteristics. For instance, the gravitational or cosmological constants arise due to the
coordinated behavior among systems of individual material objects in a universe.
Third, the philosophy of cosmology must ground the kinds of processes that are permitted at
cosmological scales and their connection with other physical processes. Now, hylomorphism
grounds the relation of individuals to their global aggregates, and this grounds the possibility of
various large-scale processes. Hylomorphism provides such a ground due to GEP. This aspect of
form as a part of CE is frequently overlooked: form is not only a principle intrinsically
determinative of a thing, but also extrinsically determines it in relation to a larger, potentially
cosmic, whole, and allows it to be determined by that ambit. Insofar as, on GEP, the properties of
individual objects are coordinated to allow a universe, there can exist cosmological processes.
In relation to all three of these points, notice that CE, UCE, and GEP are general principles
drawn from our experience of a natural order of mutable things. They are still principles of the
being of things, but precisely how they are such must be discovered through extensive empirical
inquiry. Here we recall the concern at the beginning of §1, that an empirically grounded
philosophy of nature must both contemplate the universe in general, antecedent to any of the
specific natural sciences, and yet be consequently refined by them. This consequent refinement is
what cosmology provides when it reveals the law-governed behavior, global initial conditions
and constants, and types of large-scale processes that exist in the cosmos. Hylomorphism
provides an analogical schema to unite these features at a macroscopic or cosmological scale
with the hylomorphic grounds of micro- and mesoscopic behavior.
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4.2. Composition & structure of the universe
We now turn to the second set of explananda (§1.3). First, the philosophy of nature that
grounds cosmology must permit familiar kinds, the “ordinary objects” of our experience.
However, hylomorphism possesses such compatibility outright insofar as it is discovered and
argued for in this ambit. This humble basis is what one transfers from the manifest image of the
world to the scientific image. For instance, the inferred microscopic behavior of substances is
epistemically dependent upon observations of behavior at the mesoscopic scales of our
experience. Behavior at both scales is transferred to distant objects at macroscopic, global scales.
Examples of such a transfer are the use of spectroscopy and estimates of stellar luminosity.
Second, the philosophy of cosmology must ground the existence and relationships between
local and global structure of physical objects in the cosmos. Now, hylomorphism permits the
possibility of individuals or systems of individuals at various scales, and this allows it to ground
the possibility of variegated global structure. Both UCE and GEP indicate this possibility. The
diachronic behaviors in §4.1 must originate from individuals whose natures and consequent
properties are capable of acting in those ways (UCE), and these behaviors can in turn lead to
aggregates of such individuals in larger systems (stars, planets, galaxies) that can act in
coordinated fashions through gravitation and obeying energy conservation (GEP). Such are the
specific characteristics of these aggregates discovered empirically by cosmology.
Third, the philosophy of cosmology must ground the possible kinds of objects in the universe
and the makeup of those objects (e.g., hydrogen abundance). Hylomorphism permits both the
existence and the possibility of discovery of the kinds and constitutions of individuals and
aggregates of individuals. This, in turn, permits an understanding of cosmological kinds and their
makeup. Hylomorphism permits the existence of such objects from UCE and GEP as indicated in
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the previous argument. However, it also permits the possibility of knowing such objects and their
constitutions insofar as it is explains our interaction with the ordinary objects through which we
investigate the cosmos. For instance, our knowledge of hydrogen abundance in the universe is
based upon our understanding of the spectroscopic behavior of materials at local scales in
laboratories. Insofar as a hylomorphic theory of change and structure applies at such scales and
grounds how we can know such objects through the stimulus, action, and interaction with their
powers, this also grounds our knowledge at cosmological scales.52
Finally, sound cosmological ontology must also sustain the possibility of spacetime.
52 Hylomorphism at the quantum scale presents unique challenges. Given the scale of application
of hylomorphism that we are focusing on, we must prescind from, while acknowledging, the
difficulties that the hylomorphic model faces when dealing with the synchronic structure of
substances at microscopic, quantum scales. These difficulties are active areas of research among
hylomorphists of different schools (e.g., consider Koons 2018b). Our proposals of CE, UCE, and
GEP do not require specific conclusions about the hylomorphism of quantum physics, although it
does imply a specific approach, viz., that “ordinary objects” at the mesoscopic scale (e.g., human
beings, animals) be taken as paradigmatic instances of substances. We follow Eddington (1933,
p. 37): “The twoness of two electrons is not completely like the twoness of two apples.”
Quantum non-locality also poses an as-yet unmet challenge to hylomorphism as a “local”
ontology of substances unable to act at a distance. Yet substantial form is not “localized” by
spacetime points (which are “local” in a mathematical sense); rather, substantial form is
ontologically prior to space and time. Various hylomorphic proposals include W. A. Wallace
1979, 1996; Smith 1999; and Simpson et al. (eds.) 2017. See also Kastner et al., 2018.
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Generally, hylomorphism does entail a spatial and temporal structure to the beings in the
universe and even a global structure. Insofar as hylomorphism grounds particular initial
conditions for the global aggregate of moving things, it would also permit specific spacetime
geometries, since these arise from initial conditions. The nature of space and time, however,
require further arguments and cannot be deduced from hylomorphism as a general theory.
Various intermediate steps are required, including addressing the application of mathematics to
natural, physical objects. A broadly Aristotelian philosophy of mathematics considers
mathematical objects to be constituted by mentally abstracting certain formal determinations
from the material conditions of mutability.53 This account of abstraction would contend that
53 Maritain 1995; De Koninck 1957; see also Franklin 2014 for a generally Aristotelian
approach. This view proposes a theory of mixed or subalternate sciences which claims that
mathematical principles stand as form to the matter of natural scientific considerations; see
Aquinas 1958; Mullahy 1946. It would require a longer excursion to examine how the manner of
conceiving things and (recursively) conceiving concepts influences the foundations of modern
mathematics and its physical applications, in this case, regarding the nature of spacetime. Such a
conceptual “desedimentation” regarding mathematics is undertaken by Klein 1992, and see
Hassing 2017; Klein’s approach is applied to the ontology of spacetime by Cosgrove 2018.
Hylomorphic and dispositionalist accounts of spacetime have been proposed: see Feser 2017 and
Bird 2017. The theoretical cost adopting a privileged present, contrary to the demands of
relativity, is absorbed by Unger and Smolin 2014 (see pp. 183–84, pp. 386–88) by appealing to a
“shape dynamics” approach to gravity, one that recovers relativistic mechanics while
maintaining a privileged present; see Mercati 2018 for more. It is unclear whether the same
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hylomorphism is the ground from which mathematical physics has clandestinely harvested many
fruits.54
Keeping in mind the qualifications made above (that these general principles must be
specified by empirical research), we can now say that hylomorphism grounds global regularities
and structures. CE, UCE, and GEP give us a way to see the universe as a system of substances
which exhibit various scales of law-governed behavior, whose smaller scales feature as parts or
members in the behavior and structure at larger scales. However, one qualification is that our
application of hylomorphism is limited by the present state of scientific development. This is
indicated by the lack of an accepted theory of quantum gravity. Another indication is the
“cosmological constant problem.”55 These highlight the tentative state of our cosmological
theories, and consequently the current reach of hylomorphism.
5 Resolutions to philosophical problems in cosmology
Thus far, hylomorphism has grounded the various cosmological explananda from §§1.2–3,
fleshing out our positive account. What about the two difficulties from §1.4?
5.1. The meta-law dilemma
theoretical escape route is available to hylomorphism, which typically also defends a type of
presentism.
54 Larenz 2013, pp. 496–97.
55 Some unknown factor prevents quantum vacuum energy in the universe from attaining its
predicted value that is 10120 greater than the observed one, yet that unknown does not eliminate
effects of dark energy at global scales (see Peebles and Ratra 2003, pp. 561–62).
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Hylomorphism provides the means to avoid the meta-law dilemma as follows.56 First, any
change in the global regime of laws is structured by general principles of change. However, these
general principles of change are hylomorphic. Thus, any change in the regime of laws is
hylomorphic. Consequently, hylomorphism can defend the regularity of global regularities and
avoid the “explanatory nihilism” of the meta-law dilemma. Let us expand on this argument.
Unger and Smolin’s own discussion of the meta-law dilemma advances four key ideas:
possibility landscapes, the adjacent possible, cosmological natural selection, and causal
continuity. Borrowing language from evolutionary biology, they propose that regime-changes of
laws may occur in the universe’s history, and these regimes travel a “possibility landscape” of
such regimes, analogous to how species evolve across evolutionary landscapes by exploring the
“adjacent possibilities” available to them. The adjacent possible is “what [a phenomenon] can
become next, given what it is then.”57 Our current regime of laws is therefore explained by a
process of “cosmological natural selection” over this landscape. This invokes causal continuity:
Causation always involves the force of sequence: the shaping of a before
on an after. It need not always require that this shaping by sequence
assume regular and recurrent form (ibid., pp. 293–94).
This sequence has a “form,” just not one that is mathematically law-like (“regular and
recurrent”). Now, in order to avoid the first horn of the meta-law dilemma, Unger and Smolin’s
causal continuity and adjacent possibility cannot itself be law-governed. This “shaping by
sequence” is not mathematizable as are the present universe’s laws. However, to avoid the
56 We grant for the sake of argument that the universe does exhibit law-regime changes.
57 Unger and Smolin 2014, p. 27, and see pp. 245, 301 n.
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second horn of the dilemma, the changes in the regime of laws, “the adjacent possible,” and
“causal continuity” cannot imply nominalism. Our concepts must describe real features of the
universe, even if those are changeable features. Causal continuity is still intelligible because “in
nature, as we observe it, what comes before always shapes what comes later, even if the
mechanism of influence may change” (ibid., p. 279). This describable causal influence even
persists through time and in extreme states of energy and density, for while “the range of the
adjacent possible may be large, the before may nevertheless continue to influence the after in
time. Causality survives laws” (ibid., 287; our emphasis). In other words, the causal capacity of
the universe is one of its unchanging features, like Heraclitus’s logos.
Let us call this causal continuity’s shaping, finitude, and persistence a “causal form.” Now, it
does appear from some passages that Unger and Smolin are nominalists: “As each event and
each causal link is unique in the history of the universe, they make up a vast set, when fully
described” (Unger and Smolin 2014, p. 383). In the absence of common natures, is not pure
history the only alternative? If so, this “causal form” appears to be a very weak claim. Yet Unger
and Smolin insist on a real influence between stages where different laws are operative. If these
distinct stages exhibit causal continuity, then this requires that features of the prior stage affect
the features of the posterior stage. Thus, causal continuity and the adjacent possible must be
marked by a causal form that provides finitude and limitation between the various stages of
physical laws. That is, not only does this causal form ground nature’s intelligibility, it also does
so by providing contours to the phenomena and their laws that come-to-be in the new regime.
Even if the laws were to change drastically, causality survives laws. Causality is ontologically
prior to law and serves as the ground of possibility for law. Thus, Unger and Smolin must
maintain that the “adjacent possible” is somehow contained within the prior stage by being
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causally related to the existence of the posterior stage.
Why does this analysis deserve to be characterized as hylomorphic? First, the causal form
required—as difficult as it may be to investigate empirically—is a certain ground of
intelligibility in things. Second, this causal form provides contours to the conditions, behaviors,
and laws in the universe and its stages. Finally, this causal form cooperates with a type of
possibility by which successive regimes of laws come into being. However, an innate cause of
the intelligibility, determinate actuality, and the limiting principle to potentiality in nature are
hallmarks of the formal cause. The analysis is hylomorphic. Our response becomes stronger by
looking to GEP. This character of hylomorphism allows that a regime-changing meta-law is a
deeper aspect of the universe’s nature, permitted by the fundamental matrix of universal potency
that constitutes one part of CE. Due to GEP, new regimes of law are contained at the global level
in potency and made determinate when a new regime of global form comes to be. Consequently,
a hylomorphic analysis can shore up the regularity of global regularities, even amidst putative
regime changes in the very laws of nature, and avoid the meta-law dilemma.58
5.2. The one universe
If GEP implies that the overall form of the universe permits regime-changes to its laws, then
something about the existence of the global as such and its kind must be said. Hylomorphism
grounds cosmology’s assumptions about the unity of the universe, its uniqueness, and, finally, its
type or form. Here we consider such arguments from the philosophy of nature; metaphysical
58 A position akin to Armstrong’s could appeal to higher-order universal relations, however, see
Lange 2008 against this; the discussions of Armstrong 1983, pp. 22–23, and Lange 2008, pp. 88–
90, suggest that the regularity view of laws could not avoid the meta-law dilemma.
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arguments for or against a multiplicity of universes are a separate concern.59
First, the universe is one or unified.60 This is because the universe is an aggregate of material
substances exhibiting coordinated interactivity. The coordinated interactivity arises due to both
causal and topological connections permitted by GEP. Observations into the universe’s past
indicate that the observable universe is causally connected. If portions of the unobservable,
physical universe are causally separate now, but were not in the past, they count as part of the
one universe (a “multi-domain” universe). Such causal connections are permitted by the physical
topology of the universe, which cosmologists contemplate via the spatiotemporal structure of
general relativistic models whose equations capture how mass and energy are permitted to
interact in spacetime. Now, if the aggregate of individuals in the universe exhibits such
coordinated interactivity, it forms a unified whole of individuals, a system, for what acts as one
exists as one in some sense of “one.” Here, the relevant sense of “one” is the unity that belongs
to the order of numerically distinct substances. This argument stakes hylomorphism’s claim
against both monism and a Neo-Humean view; it concludes that the universe is unified.
Second, the universe is unique or one in number. Multiverse claims possess prima facie
plausibility insofar as types (e.g., “universe”) can receive different instantiations (e.g., “this
universe” or “that universe”).61 While a distinction of this sort is not logically impossible, it
59 Some cosmologists recognize that there are such arguments proper to natural philosophy in
this sense (Unger and Smolin 2014), or at any rate arguments that are closer to the sciences on
this topic (Ellis 2014, pp. 11–13).
60 See also Juarez 2017 for a similar argument.
61 Compare Aristotle, De Caelo I.9.
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might be that it is physically impossible. This would be the case if the universe, as an aggregate
of individuals, is composed of all available matter, that is, if the potency for instantiation is
exhausted. A universe composed of all available matter would be unique, for there would be no
matter to instantiate another instance of its kind. Now, on the strength of the conclusion about the
unity of the universe due to its causal and topological connectedness, the present universe—even
if a multi-domain one—does contain all available matter. In other words, if there were matter
(mass-energy) that were neither causally nor topologically connected of its nature to the present
universe, then such matter—if “matter” is not pure equivocation in that case—as causally and
topologically disjoint could not be contemplated by the principles of cosmology.62 Such matter in
putative para-universes is not a physical possibility in the sense that countenancing such
possibilities lies outside the scope of cosmology.63 Hylomorphism grounds this reply insofar as
material potency is the disposition for singulars, a principle of numerical individuation: “Those
who speak of ‘heaven’ speak of the form, but those who speak of ‘this heaven’ speak of form in
matter.”64 Now, the logical possibility of para-universes lies beyond the scope of cosmology as a
science or hylomorphic natural philosophy; it is a metaphysical issue.
62 Aristotle also argues from the causal and physical-topological unity of the universe to its
numerical unity (see De Caelo I.8); however, his universe’s topology lacked extensive
symmetries (it had one spherical boundary with one center); see Jammer 1993, pp. 219–21;
Earman 1989. However, the spirit of his argument seems sound.
63 This is echoed by many critiques of the multiverse (para-universe) hypothesis; for instance,
see Ellis and Silk 2014.
64 Aquinas 1886, In De Caelo, lib. 1, lect. 1, n. 2
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Third, hylomorphism can articulate the form belonging to the universe, for this form is
constituted through the types of coordinated interactivity of the natures composing that form. Let
us contrast this with two other views. On the one hand, Schaffer’s monism could also defend an
“essence” for the universe—it would be identical with the one and only substance that obeys the
fundamental laws of physics. Such an essence could be spelled out, on his view, by appealing to
the global behavior that is captured by fundamental physics. On the other hand, and in a quite
different way, a Neo-Humean could claim that a single description of the universe at its broadest
scale through the global laws supervening upon the total mosaic of spacetime points describes
the “essence” of the world. However, if one does not wish to “go fully global” in either of these
ways, what could one say?
Perhaps the law-like behavior exhibited by the universe—e.g., as captured in conservation
principles—supervenes on or is emergent from the dispositions of individual objects. Brian Ellis
suggests that such conservation laws are “of the essence of the global kind in the category of
objects or substances” (Ellis 2005, pp. 91–92). So, global behaviors are manifestations of a
global disposition that constitutes the essence of the world, independent of individual objects.
Chakravartty (forthcoming) proposes something similar: “Why not think of the relevant
dispositions regarding conservation as properties of the system itself, as opposed to properties of
the things constituting or inhabiting it?” In this sense, conservation laws would be properties
belonging to the world itself as a system, properties which are in some sense necessary
conditions for local processes. Bigelow, Ellis, and Lierse 1992 conclude that “conservation laws
are best understood as ascribing properties to the world as a whole, properties which are essential
to the natural kind to which our world belongs” (p. 385). However, they also suggest that this
global essence may depend in part upon individual things: “Essences of things in the world, and
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correlations which depend on the essences of such things, may both contribute to the essence of
the world as a whole” (ibid., p. 386; see p. 372).
Hylomorphism motivates a similar conclusion since the forms of individual substances are
not intelligible and are not causes in isolation, but are intelligible causes relating types of
individuals to each other as parts of a larger whole. (The difficulty of achieving this view of the
whole explains the appeal of a Neo-Humean position countenancing recombination at globally
supervening scales.) This conclusion is permitted by UCE and GEP, and it is empirically
supported through investigations into the behavior and development of large-scale systems and
biological organisms at cosmological and geological timescales. Thus, the forms of individuals
are—via essential, extrinsic, and determinable relations—formal parts of a cosmic whole.
Hylomorphism is able to provide a philosophical ground for the universe having its own form
through GEP, since this allows us to contemplate a type that contains as defining elements the
interconnected dispositions and behaviors of its parts or member substances. This comports with
the thesis of past hylomorphists that the form of the universe—the natural kind of the world—is
the very unity of order of the kinds of mutable beings constituting it.65
Consequently, hylomorphism is the basis for cosmology’s ability to study the global as such
and of its being a science about a unique historical totality, for it grounds the possibility of
studying a total, unique, and unified object, the universe. Hylomorphism does this insofar as it
argues that the universe is unified and unique. It can also argue to this conclusion from the
connectedness of the micro-, meso- and macroscopic scales, taking as a basis in this regard the
65 See Aquinas 1918, ScG, II.39: “The form of the universe consists in the distinction and order
of its parts.” These “parts” are primarily kinds and secondarily individuals; see Blanchette 1992.
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typical view among scientists and some philosophers that the universe’s history is characterized
by an increase in complexity.66 On a hylomorphic view of this development, it is arguable that
the cosmos would have begun in a state of substantial simplicity, and out of this initial composite
more complex beings and structures came to be.67 Put another way, if it is the case that the initial
conditions of the universe at quantum scales included fluctuations of matter “magnified” through
inflation to make the seed perturbations that caused the beginnings of large-scale structure
formation throughout the universe, eventually leading to the conditions for life (see Ellis 2016,
pp. 276–80), then the universe from its earliest stages is connected on all scales through this
causal process, which at later times permits the observed complexity at all scales, especially that
of living things. However, hylomorphism grounds the analogical unity of all these scales.
Hylomorphism, therefore, allows the total global aggregate of mutable substances to be the
unique unified system, the cosmos.
However, what justifies our use of “total” in the previous paragraph? Or, to recall the
problem from §1.1, what allows us to speak of “the Universe” as the fundamental background
concept in cosmology? We noted at the outset of this section that the topic of the universe is
discussed here from the perspective of natural philosophy, not metaphysics. A defense of the
existence and intelligibility of “the Universe as such” is a metaphysical issue, in the sense that
one doubting either or both would be doubting the very domain of discourse and principles that
both natural philosophy and cosmology must assume but neither can defend. Consequently,
66 For instance, see Prigogine and Stengers 1984; Chaisson 2001 and 2005; Novo et al. 2018;
Maritain 1997; De Koninck 2008.
67 See De Koninck 2008, pp. 284, 297–98, 314; Dumsday 2011; Koons 2018b, p. 162.
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Aristotle placed the burden on metaphysics to defend the assumptions of the particular sciences
(Physics I.2; Metaphysics IV.1). This is also a metaphysical topic due to the nature of the
arguments one would have to make. Consider how Aquinas, apart from Aristotelian natural
philosophical arguments, defended the uniqueness of the universe against objections that a
“multiverse” was possible. These arguments involve lines of reasoning that are clearly
metaphysical: e.g., causal regress arguments to God or discussions of God’s activity.68 In like
fashion, the final coherent vision of why the cosmos is one or why there is an ordering of the
parts of the universe to each other, and not just that it is so, as grounded above by hylomorphism,
would involve one in classical regress arguments about efficient and teleological causes. Such
arguments are favored by hylomorphists who are also theists, noting that both the unity of the
cosmos (Juarez 2017) as well as the diversity of kinds in the universe call for explanation. As to
the latter, theists even propose to explain such diversity in terms of a “quasi-deduction” of the
order of the universe.69 (Such arguments shed light on the plausibility of Platonic grounds for the
68 See Aquinas 1884, In De Caelo, lib. 1, lect. 19, n. 197. Aquinas argues that the uniqueness of
the world could be inferred from the oneness of its First Mover; he argues that its uniqueness
follows from its unified order to the First Mover as an end; he argues that, even were God able to
make para-universes, this would either be contrary to his wisdom (if they were wholly alike) or
the complete set of such universes would itself be the universe (if they each exhibited diverse
perfections); and he argues that the essence of the world and its goodness is “more powerful” in
its own kind by being one and not many in number.
69 Just such a theistic “quasi-deduction”—the name is from Geiger 1953, p. 397, n.—of the
universe from the nature of divine causality is proposed by Aquinas 1926, ScG, III.97.
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philosophy of cosmology, insofar as natures’s laws originate as ideas in the mind of God.) We
conclude that if one wishes to defend the existence of the Universe as such in the sense of why it
exists as it does, metaphysical arguments are necessary. Metaphysical truths and realities, and the
cogency of our grasp of the same, ground even the hylomorphic foundations of cosmology
presented here.
6 World enough and form
We conclude that cosmology needs hylomorphism. This is because hylomorphism is able to
ground global regularities and structures, the regularity of global regularities, and the existence
of the global as such. It does this by accounting for changing substances with cosmic essences
(CE) and thus aggregates of substances, the various scales and domains of law-governed
behavior rooted in the natures of those substances (UCE), and how those substances as parts
relate to the universe as a unique, unified whole (GEP). It also resolves philosophical problems
that arise in cosmology and shores up the cosmologist’s intuition of studying a unique, unified
totality with an fascinating, intelligible history. Given hylomorphism’s close affinity with
teleology (in Aristotelianism) and with theism (in Thomism), one might also expect that
arguments along these lines could be developed. However, these must be the concerns of other
essays.70 At present, we hope to have sufficiently drawn up the blueprints to the hylomorphic
foundations for the philosophy of cosmology. Hylomorphism initiates the local natural
philosophy of the non-living, the living, and even the human being, the mikrokosmos. It is
likewise able to ground the natural philosophy of the cosmos.
70 Consider Peterson 1996 and Dumsday 2012; Beltrán 2001 and 2016.
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Acknowledgements
This paper was produced as part of the author’s postdoctoral research project, supported by a
grant from CONICYT, FONDECYT, Postdoctoral Proj. No. 3170446. The author gratefully
acknowledges this financial support and the faculty and staff of his home institution, Pontificia
Universidad Católica de Chile, Instituto de Filosofía. Research for this paper was also conducted
at the University of Notre Dame, as a guest of the John J. Reilly Center for Science, Technology
and Values and the Jacques Maritain Center, and the author thanks Anjan Chakravartty, John
O’Callaghan, and their staff for their support and hospitality during that visit. The two
anonymous reviewers also receive the author’s thanks for their substantive and insightful
comments, which have helped to improve the paper tremendously. The author also gives thanks
to many others for their comments, conversations, and suggestions for this paper and its topics,
while retaining all blame for remaining errors: José Tomás Alvarado, Oscar Leon, Fr. Phillip
Neri Reese OP, Martin Beers, Fr. Thomas Davenport OP, Ryan Shea, Nicholas Teh, Anjan
Chakravartty, Jack Cahalan, Matthew Minerd, Marco Stango, Andrew Seeley, Marina Brungardt,
and the attendees of the 2017 IIo Congreso Latinoamericano de Filosofia Cientifica and the 2017
Meeting of the American Catholic Philosophical Association for their comments on predecessor
versions of this paper. Finally, in thanks for her insights into cosmology that have helped his own
thinking, the author dedicates this paper to Dr. Carol Day.
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